Plastid transformation in Arabidopsis thaliana

ABSTRACT

The invention provides methods and compositions for obtaining transplastomic  Arabidopsis  plants. Specifically, the method provides culturing protocols and compositions that facilitate the regeneration of transformed plants following delivery of exogenous DNA molecules.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application claims priority under 35 U.S.C. §371 to international application PCT/US97/03444, filed on Mar. 6, 1997, and published as WO97/32977, which in turn claims priority from U.S. Application No. 60/012,916, filed on Mar. 6, 1996.

Pursuant to 35 U.S.C. Section 202(c), it is acknowledged that the United States government has certain rights in the invention describe herein, which was made in part with funds from the National Science Foundation Grant Number, MCB 93-05037.

FIELD OF THE INVENTION

The present invention relates to the field of transgenic plants. Specifically, the invention provides compositions and methods for the transformation of plastids in plants from the Cruciferae family.

BACKGROUND OP THE INVENTION

Several publications are parenthetically referenced in this application in order to more fully describe the state of the art to which this invention pertains. Full citations for these references are found at the end of the specification. The disclosure of each of these publications is incorporated by reference in the present specification as though set forth herein in full.

The plastid genome of higher plants is a circular double-stranded DNA molecule of 120-160 kb which may be present in 1,900-50,000 copies per leaf cell (Palmer, 1991; Bendich, 1987). Stable transformation of the tobacco plastid genome (plastome) has been achieved through the following steps: (i) introduction of transforming DNA, encoding antibiotic resistance, by the biolistic process (Svab et al. 1990a; Svab and Maliga 1993) or PEG treatment (Golds et al. 1993; O'Neill et al., 1993), (ii) integration of the transforming DNA by two homologous recombination events and (iii) selective elimination of the wild-type genome copies during repeated cell divisions on a selective medium. Spectinomycin resistance has been used as a selective marker encoded either in mutant plastid 16S ribosomal RNA genes (Svab et al. 1990a; Staub and Maliga 1992; Golds et al. 1993), or conferred by the expression of an engineered bacterial aadA gene (Svab and Maliga 1993). Vectors which utilize aadA as a selectable marker gene and target the insertion of chimeric genes into the repeated region of tobacco plastid genome are available (Zoubenko et al., 1994). Selection of plastid transformants by kanamycin resistance, based on the expression of neomycin phosphotransferase (kan gene), is more difficult but also feasible (Carrer et al., 1993; Carrer and Maliga, 1995).

To date, stable plastid transformation in higher plants has been reported in tobacco only (reviewed in Maliga, 1993; Maliga et al., 1993). Transplastomic plants from other agriculturally and pharmaceutically important species are highly desirable. Expression of foreign genes of interest in the plastids of higher plants in the family Cruciferae provides several advantages over nuclear expression of foreign genes. These are 1) expression of exogenous DNA sequences in plastids eliminates the possibility of pollen transmission of transforming DNA; 2) high levels of protein expression are attainable; 3) the simultaneous expression of multiple genes as a polycistronic unit is feasible and 4) positional effects and gene silencing which may result following nuclear transformation are also eliminated.

SUMMARY OF THE INVENTION

The present invention provides improved methods for the generation of stably transformed, transplastomic plants. In one embodiment of the invention, cotyledon cells are cultured in high auxin liquid medium for a sufficient time period to stimulate uniform cell division. Initial culture is at a high density (50-200 cotyledons/20 ml). The cotyledons are then transferred to agar-solidified medium for delivery of exogenous, transforming DNA. Following delivery of transforming DNA, the cotyledons are transferred at a lower density (25-30/50 ml) to a medium containing high cytokinin level and the selection agent to facilitate selection of transformants and plant regeneration. Presence of the exogenous DNA in the plastid genome is then confirmed by Southern blot analysis or PCR.

The transforming DNA molecules of the invention have several distinct features. These are 1) targeting segments flanking the foreign gene of interest consisting of plastid DNA sequences from the plant to be transformed, thereby facilitating homologous recombination of the transforming DNA into a pre-determined region of the plastid genome; 2) a selectable marker gene disposed within the targeting segment, conferring resistance to a selection agent; 3) 5′ and 3′ regulatory sequences derived from plastid DNA operably linked to sequences encoding a foreign gene of interest thereby enhancing expression of the transforming DNA and stability of encoded mRNA; and 4) at least one cloning site adjacent to the selectable marker gene for insertion of the foreign gene of interest which by itself is not selectable. Since the selectable marker gene and the foreign gene of interest form a heterologous block of contiguous sequence, integration of both genes into the plasid genome is effected.

In another embodiment of the invention, leaf cells are initially treated with high auxin media, followed by transformation with the transforming DNA and culturing in the presence of high cytokinin levels and a predetermined selection agent. Cells containing transformed plastids are maintained in the presence of the selection agent facilitating the obtention of homoplasmic cells which can then be regenerated into transplastomic plants.

Thus, the present invention provides novel methods and compositions for creating transplastomic plants. The genus Arabidopsis belongs to the mustard or crucifer family (Brassicaceae or Cruciferae), a widely distributed family of approximately 340 genera and 3350 species. The family is of significant economic importance as a source of vegetable crops, oil seeds, spices and, to a lesser extent, ornamentals. Much of its agricultural importance derives from the genus Brassica. Examples for Brassica ssp. of economic importance are: Brassica napus (oil seed), Brassica juncea (oil seed), Brassica campestris (oil seed), Brassica juncea (oil seed), Brassica oleracea (broccoli, cauliflower, cabbage) Brassica nigra (black mustard) and Brassica hirta (white mustard).

Plastid transformation in Arabidopsis thaliana a model species for plant research (Meyerowitz and Sommerville, 1994) and Brassica ssp., an important agricultural crop is exemplified herein. These methods are suitable for transformation of plastids in other plants from the Cruciferae family.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-1C are a schematic drawing illustrating the integration of aadA into the Arabidopsis plastid genome (ptDNA) after transformation with plasmid pGS31A. FIG. 1A shows a map of the transformation vector pGS31A, the ptDNA region containing the integrated spectinomcycin resistance (aadA) gene (T-ptDNA) and the cognate region of the wild-type ptDNA. 16SrDNA, rps12/7 and trnV are plastid genes (Shinozaki et al., 1986). FIG. 1B shows the regions of ptDNA contained in the P1 and P2 probes. FIG. 1C is an autoradiogram showing the results of Southern blot hybridization confirming integration of aadA in the plastid genome. The P1 targeting sequences hybridize to a 2.72-kb fragment in the wild-type (At) plants and to a larger, 3.82-kb fragment in the transplastomic line (At-pGS31A-16). Note absence of wild-type fragment in transplastomic line. The aadA probe, P2, hybridizes only to the larger transplastomic fragment.

FIG. 2 is a schematic diagram of the plastid transformation protocol used for Arabidopsis leaves.

FIG. 3 is a schematic diagram of the different protocols used for obtaining fertile Arabidopsis plants from cotyledonary explants of Arabidopsis thaliana (RLD) having transformed plastids.

FIG. 4 is a map of the plastid targeting region of pGS7 and pGS85A plasmids. Note unique HincII cloning site in plasmid pGS7 and KpnI restriction site in plasmid pGS85, and chimeric kan kanamycin resistance gene. The plastid genes trnV, 16SrDNA and rps12/7 are described in Shinozaki et al., 1986. Site and direction of transcription initiation is indicated by horizontal arrow.

FIG. 5 is a sequence of the targeting region of plasmid pGS7. The genes conferring resistance to kanamycin or spectinomycin will be inserted into the marked Hinc II site

FIG. 6 is a sequence of the plastid targeting region of plasmid pGS31A.

FIG. 7 is the sequence of the plastid targeting region of plasmid pGS85A.

DETAILED DESCRIPTION OF THE INVENTION

Insofar as it is known, plastid transformation has been demonstrated in tobacco only. A protocol for the transformation of plastids in Arabidopsis thaliana and Brassica napus has now been developed and the methods utilized to create these transformants are set forth below. The use of Arabidopsis and Brassica in the following examples is meant to be illustrative of the methods of the invention. The methods disclosed herein may be adapted to other plants in the Cruciferae family.

The plastids of Arabidopsis thaliana have been transformed following biolistic delivery of transforming DNA into leaf cells on the surface of microscopic (1 μm) tungsten particles as described below in Example I. The transforming plasmid pGS31A, used for these experiments carries a spectinomycin resistance (aadA) gene flanked by plastid DNA sequences to target its insertion between trnV and the rps 12/7 operon. Integration of aadA by two homologous recombination events via the flanking ptDNA sequences and selective amplification of the transplastomes on spectinomycin medium yielded spectinomycin resistant cell lines. Regenerated plants were homoplasmic in that the plastid genome copies had been uniformly altered by the transforming DNA. The efficiency of plastid transformation was low, two in 201 bombarded leaf samples. However, none of the 98 plants regenerated from the two lines were fertile.

These fertility problems were likely attributable to extended periods of treatment with 2,4-D, an auxin (Van der Graaff and Hooykas, 1996). It is possible that shortening exposure time to this agent may overcome the fertility problem. The relatively long growth period of Arabidopsis thaliana to provide a suitable source of leaves for transformation also makes leaves a less desirable tissue source.

Cotyledons and leaves each contain an abundant number of plastid genome copies per cell. Additionally, cotyledons provide a more available tissue source. Accordingly, cotyledon cells have been utilized as recipients for transforming DNA as set forth in Example II below. Cotyledon cells are preferred over leaf cells for practicing the methods of the present invention due to the relatively short (7 days) culturing period to prepare the cells for bombardment with transforming DNA. Another advantage to using cotyledon cells as the target cell is the reported regeneration of fertile Arabidopsis plants from immature cotyledons in the absence of 2,4-D (Patton and Meinke, 1988). In addition, protocols have been described for the regeneration of fertile Arabidopsis plants from leaf explants, also in the absence of 2,4-D (Lloyd et al., 1986; Van der Graaff and Hooykas, 1996).

As described in Example III, Arabidopsis thaliana and Brassica napus belong to the same family, Cruciferae, and therefore the plastid genomes share a high degree of homology and are essentially identical (Palmer et al., 1994). Accordingly, plastid transformation vectors and expression cassettes developed for Arabidopsis can be used for plastid transformation and expression of foreign genes in Brassica species without modification.

The following definitions are provided to facilitate an understanding of the present invention:

Heteroplasmic: refers to the presence of a mixed population of different plastid genomes within a single plastid or in a population of plastids contained in plant cells or tissues.

Homoplasmic: refers to a pure population of plastid genomes, either within a plastid or within a population contained in plant cells and tissues. Homoplasmic plastids, cells or tissues are genetically stable because they contain only one type of plastid genome. Hence, they remain homoplasmic even after the selection pressure has been removed, and selfed progeny are also homoplasmic. For purposes of the present invention, heteroplasmic populations of genomes that are functionally homoplasmic (i.e., contain only minor populations of wild-type DNA or transformed genomes with sequence variations) may be referred to herein as “functionally homoplasmic” or “substantially homoplasmic.” These types of cells or tissues can be readily purified to homoplasmy by continued selection on the non-lethal selection medium. Most seed progeny of such plants are homoplasmic in the absence of selection pressure, due to random sorting of plastid genomes.

Plastome: the genome of a plastid.

Transplastome: a transformed plastid genome.

Transformation of plastids: stable integration of transforming DNA into the plastid genome that is transmitted to the seed progeny of plants containing the transformed plastids.

Selectable marker: the term “selectable marker” refers to a phenotype that identifies a successfully transformed organelle, cell or tissue, when a gene or allele encoding the selectable marker is included in the foreign DNA used for transformation.

Transforming DNA: refers to homologous DNA, or heterologous DNA flanked by homologous DNA, which when introduced into plastids replaces part of the plastid genome by homologous recombination.

Targeting segment: refers to those homogologous flanking regions which facilitate homologous recombination between foreign DNA and the plastid genome.

Translationally fused: refers to two coding DNA segments within a construct derived from different sources spliced together in a construct such that a chimeric protein is expressed.

High auxin culture medium: plant tissue culture medium which contains auxin only, or a combination of high concentration of auxin and very low concentrations of cytokinins. The response of a plant cell to an auxin is specific for a given taxonomic group. When different auxins are applied in combination, their effects may not be additive. Furthermore, the tissue response to auxin may be modified by cytokinins. Accordingly, the type and concentration of auxin used should be determined empirically for the species to be transformed. A preferred example of a high auxin medium for use in the present invention is C1 medium, containing 1 mg/ml of the auxin 1-naphthaleneacetic acid (NAA) and a low concentration (0.2 mg/ml) of the cytokinin 6-benzylaminopurine (BAP). Other, auxins, such as indole-3-acetic acid (IAA) and dichloro-phenoxyaceticacid (2,4-D) may also be used to stimulate uniform cell division.

High cytokinin culture medium: Like the response of plant cells to high auxin media, the response of plant cells to high cytokinin media is taxonomic group specific. An example of a preferred high cytokinin medium for use in the present invention is C medium, containing 1 mg/L of BAP, 2 mg/L of 2iP, (6-(gamma, gamma-Dimethylallyamino) purine or IPA, N6-(Isopentenyl) adenin) and a low concentration of the auxin NAA (0.1 mg/L). Other cytokinins which may be used include 6-furfurylaminopurine (KIN or kinetin).

The detailed description provided in the following examples relates to preferred methods for making and using the DNA constructs of the present invention and for practicing the methods of the invention. Any molecular cloning and recombinant DNA techniques not specifically described are carried out by standard methods, as generally set forth, for example in Sambrook et al., “DNA Cloning, A Laboratory Manual,” Cold Spring Harbor Laboratory, 1989 or Ausubel et al. eds. in “Current Protocols in Molecular Biology”, John Wiley and Sons, 1995.

The following examples are provided to more fully describe the instant invention. They are not intended to limit the scope of the invention in any way.

EXAMPLE I Plastid Transformation in Arabidopsis Leaves by Selection for Spectinomycin Resistance

The following materials and protocols enable the practice of the methods of Example I. A schematic diagram of the methods utilized is provided in FIG. 2.

Plant Material

As the recipient for transformation, the Arabidopsis ecotype RLD was used. This ecotype has been reported to regenerate readily in culture (Marton and Browse, 1991).

Construction of Vector pGS31A

The Arabidopsis plastid transformation vector pGS31A is shown in FIG. 1. The immediate progenitor of pGS31A is plasmid pGS7, a pBluescript KS(+) phagemid vector (Stratagene) derivative. Plasmid pGS7 carries a 2-kb HindIII-EcoRI Arabidopsis ptDNA fragment containing the 5′-end of the 16S rRNA gene, trnV and part of the rps12/7 operon. During construction of the pGS7 plasmid the HindIII site has been removed by digestion with HindIII (site in 16SrDNA) and KpnI (in vector, treated with the T4 DNA polymerse to remove the single-stranded overhangs) and ligating the blunt ends. Vector pGS31A carries the selectable spectinomycin resistance gene, (Prrn::aadA::TpsbA) present in plasmid pZS197 (Svab and Maliga, 1993). The aadA coding region is transcribed from a synthetic promoter consisting of the promoter of the tobacco rRNA operon fused with a synthetic ribosome binding site (Prrn). The aadA mRNA is stabilized by transcriptionally fusing sequences downstream of the coding region with the 3′-untranslated region of the tobacco plastid psbA gene (TpsbA). The gene in pGS31A derives from a modified progenitor of pZS197 in which the XbaI site between aadA and TpsbA was removed by blunting. Plasmid pGS31A was obtained by excising the chimeric aadA gene with Ecl136II (an isochisomer of SacI, yields blunt ends) and BspHI (single-stranded overhang filled in to obtain blunt ends) for ligation into the unique HincII site of plasmid pGS7 between trnV and the rps12/7 operon.

Tissue Culture Media

The tissue culture protocols were adopted from Marton and Browse (1991) and Czako et al. (1993). The Arabidopsis tissue culture media (ARM) are derivatives of the Murashige & Skoog (1962) MS medium. ARM medium: MS salts, 3% sucrose, 0.8% TC agar, 2 ml/L of the vitamin solution (100 mg myo-inositol, 5 mg vitamin B1, 0.5 mg vitamin B6, 0.5 mg nicotinic acid, 1 mg glycine and 0.05 mg biotin per ml). ARMI medium: ARM medium containing 3 mg indoleacetic acid (IAA), 0.15 mg 2,4-dichlorophenoxyacetic acid (2,4-D), 0.6 mg benzyladenine (BA) and 0.3 mg isopentenyladenine (IPA) per liter. ARMIIr medium: ARM medium supplemented with 0.2 mg/L naphthaleneacetic acid (NAA) and 0.4 mg/L IPA. Arabidopsis shoot induction (ASI-N1B1) medium: ARM medium supplemented with 1 mg/L NAA and 1 mg/L BAP. The Arabidopsis shoots were rooted on ARM medium. Arabidopsis seed culture (ARM5) medium: ARM medium supplemented with 5% sucrose. The stocks of plant hormones were filter sterilized, and added to media cooled to 45° C. after autoclaving.

Selective media contained 500 mg/L spectinomycin HCl and/or streptomycin sulfate. The antibiotics (filter sterilized) were added to media cooled to 45° C. after autoclaving.

Cultivation of Arabidopsis Plants in Sterile Culture

For surface sterilization, seeds (25 mg) were treated with 1 ml of commercial bleach (5.25% sodium hypochlorite) in an Eppendorf tube for 5-7 minutes with occasional vortexing. The seeds along with the bleach were poured into a 15 ml conical centrifuge tube containing 10 ml 90% ethanol and incubated for 5-7 minutes. The ethanol-bleach mix was decanted, and the seeds were washed 4 times with 10 ml autoclaved deionized water and finally resuspended in sterile water (approximately 150 seeds/ml). The resulting seed suspension (2 ml) was poured into 10 cm deep (10 mm high) petri dishes containing 50 ml ARM5 medium. The seeds were spread evenly by swirling the suspension. The water was then removed from the plates by pipetting. The seeds germinated after a 10-15 day incubation at 24° C. during which the plates were illuminated for 8 hours using cool-white fluorescent tubes (2000 lux).

To grow plants with larger leaves, seedlings were individually transferred to ARM5 plates (10 plants per 10 cm petri dish) and illuminated for 8 hours with cool-white fluorescent bulbs (lux; 21° C. day and 18° C. night temperature). The thick, dark green leaves, 1 cm to 2 cm in size, were harvested for bombardment after 5-6 weeks.

Transformation and Selection of Spectinomycin Resistant Lines

Leaves (approximately 1.5 to 30 mm in length) for plastid transformation were harvested from aseptically grown plants. To cover a circular area 4 to 5 cm in diameter, 12 to 18 leaves were placed on agar-solidified ARMI medium. The pGS31A vector DNA was introduced into leaf chloroplasts by the biolistic process, on the surface of microscopic (1 μm) tungsten particles using a helium-driven PDS1000 biolistic gun. Fresh leaves were bombarded at 450 psi (target placed at 9 cm from rupture disk; position No. 3 from top in the biolistic gun). Leaves cultured for 4 days on ARMI medium were bombarded at 1100 psi (target placed at 12 cm from rupture disk; position No. 4 from top in the biolistic gun).

Leaf bombardment was performed in ARMI medium. Following bombardment, the leaves were incubated for two additional days in ARMI medium. After this time period, the leaves were stamped with a stack of razor blades to create a series of parallel incisions 1 mm apart. It has been observed previously that mechanical wounding is essential to induce uniform callus formation in the leaf blades. The stamped leaves were transferred onto the same medium (ARMI) containing spectinomycin (500 mg/ml) to facilitate preferential replication of plastids containing transformed ptDNA copies. The ARMI medium induces division of the leaf cells and formation of colorless, embryogenic callus. After 7-10 day selection on ARMI medium, spectinomycin selection was continued on the ARMIIr medium which normally induces greening. Since spectinomycin prevents greening of wild-type cells, only spectinomycin-resistant cells formed green calli. Visible green cell clusters on the selective ARMIIr medium appeared within 21 to 70 days.

In 201 bombarded samples 19 spectinomycin-resistant lines were obtained. Plant regeneration was attempted in 14 spectinomycin-resistant lines, and succeeded in 10 of them. Shoots from the green calli regenerated on the ASI-N1B1 medium, and were rooted on ARM medium.

Table 1 sets forth the recovery of spectinomycin resistant cell lines after biolistic delivery of plasmid pGS31A.

TABLE 1 Recovery of spectinomcyin resistant lines after bombardment of A. thaliana with plasmid pGS31A Number of Number of Transgenic Spont. DNA¹ Samples psi² Spc^(r) Plant pt Nucleus mutant. N/A 100 1 0 1 pGS31A 40 1100 8 6 1 7 0 pSG31A 151 450 11 8 1 10 0 ¹The control plates were not bombarded. ²psi = pounds per square inch, the value of repture disk.

Southern Hybridization Analysis of Total Cellular DNA to Verify Plastid Transformation

Spectinomycin resistance may be due to expression of aadA in plastids (Svab and Maliga, 1993), expression of aadA in the nucleus (Svab et al., 1990b), or spontaneous mutation (Fromm et al., 1987; Svab and Maliga, 1991). Southern hybridization was performed to identify plastid transformants in the spectinomycin resistant lines isolated. Total cellular DNA was isolated according to Mettler (1987). Restriction enzyme-digested DNA was electrophoresed in 0.7% agarose gels and transferred to nylon membrane (Amersham) using the PosiBlot transfer apparatus (Stratagene). Blots were probed by using Rapid Hybridization Buffer (Amersham) with ³²P labeled probes generated by random priming (Boehringer-Mannheim). When using the targeting ptDNA as a probe, in lines At-pGS31A-2 and At-pGS31A-16, the 3.82-kb transgenic fragment was the only fragment detected indicating that the wild-type ptDNA copies have been selectively diluted out during cell divisions on the selective medium. The same transgenic fragment also hybridized with the aadA probe (FIG. 1C).

Among the 19 spectinomcycin resistant lines 17 nuclear transformants were identified by a wild-type fragment on Southern blots when hybridizing with the targeting ptDNA probe. Note that the Southern blots used were optimized for the high-copy (10,000 per cell) leaf ptDNA and will not give a signal with a few nuclear aadA copies.

Spontaneous mutants are expected to have wild-type ptDNA targeting fragment on Southern blots and no PCR-amplifiable aadA gene. In the sample of 19 spectinomycin resistant lines, no such spontaneous mutant was found.

PCR Amplification of Inserted aadA Sequences

DNA was amplified according to standard protocols (1 min at 92° C., 1.5 min at 58 ° C., 1.5 min at 72° C., 30 cycles). Spectinomycin resistance being the result of aadA expression may be verified by PCR amplification of an 407 nucleotide internal segment using the following primers:

5′-GCTTGATGAAACAACGCGG-3′

5′-CCAAGCGATCTTCTTCTTGTCCAAG-3′.

Transplastomic Arabidopsis Plants

While the transplastomic Arabidopsis plants all flowered, none of them set seed after selfing, or after fertilization with pollen from wild-type plants. Included among these were 98 plants regenerated from the two lines in which spectinomcycin resistance was due to plastid transformation, and 66 plants regenerated from 12 lines in which spectinomcycin resistance was due to expression of aadA in the nuclear genome.

Conclusions and Implications

An important agricultural breakthrough, plastid transformation in the model species Arabidopsis thaliana is described in the instant invention. Based on the foregoing results, it has been found that a chimeric aadA gene, when inserted in the Arabidopsis ptDNA targeting cassette, was suitable to recover plastid transformants following biolistic delivery of the transforming DNA. However, the number of Arabidopsis plastid transformants was significantly lower, about one in 100, than anticipated based on the transformation of tobacco plastids which yields on average one transformant per bombarded sample (Svab and Maliga, 1993; Zoubenko et al., 1994). There may be multiple reasons for the relatively low transformation efficiency. Inherent species-specific differences, such as relatively inefficient homologous recombination system in Arabidopsis chloroplasts could be one obvious reason.

In tobacco vector pZS197, aadA is flanked by 1.56-kb and 1.29-kb of ptDNA, and yields—1 transformant per bombardment (Svab et al., 1993). In plasmid pRB15, also a tobacco vector, aadA is flanked by larger targeting segments, 1.56-kb and 3.6-kb of ptDNA, and yields approximately 5 plastid transformants per bombardment (Bock and Maliga, 1995). In Arabidopsis vector pGS31A aadA is flanked only by approximately 1-kb plastid targeting sequence on both sides. Therefore, the efficiency of plastid transformation in Arabidopsis may be significantly improved by increasing the size of the targeting ptDNA fragment.

In contrast to tobacco, in which most of the plants regenerated from leaves are fertile, it was surprising to find that none of the 164 regenerated Arabidopsis plants set seed. Lack of fertility, in part, may be due to the extensive polyploidy of leaf tissue as reported by Galbright et al., (1991) and Melaragno et al. (1993). An additional reason for lack of fertility may be the prolonged exposure of the cultures to 2,4 D (Van der Graaff and Hooykaas, 1996).

EXAMPLE II Plastid Transformation in Arabidopsis Cotyledons by Selection for Kanamycin Resistance

Plastid transformation has been obtained in Arabidopsis thaliana by selection for spectinomycin resistance in leaf cultures following bombardment with DNA-coated tungsten particles, as set forth in Example I. While plastid transformation has been successful, the regenerated plants were not fertile. These obstacles have been overcome by altering certain parameters of the transformation protocol.

The protocol developed and set forth in this Example has the following salient features: (1) Cotyledons obtained by germinating mature seed are used to advantage because of their ready availability, and the ease by which large quantities of sterile cotyledons are obtained from surface-sterilized seed. (2) The protocol has two distinct steps. The first step employing a high auxin medium to induce uniform cell division throughout the cotyledon (Stage I) and the second step including a high cytokinin medium to induce plant regeneration (Stages II and III). The protocol was designed to either minimize exposure to medium containing 2,4-D during tissue culture, or more preferably to eliminate such exposure completely. (3) Initial culturing of the cotyledon cells at a high density, i.e., 500-200 cotyledons/20 ml in liquid culture medium during the first 8 days (Stage I, II) proved essential for obtaining abundant plant regeneration later.

The protocol for plastid transformation in Arabidopsis utilizing cotyledons as target tissue and kanamycin-resistance as a selective marker was implemented as follows. The chimeric kan gene derives from plasmid pTNH7, a pUC118 derivative encoding neomycin phosphotransferase (NPTII), an enzyme which enzymatically inactivates the kanamycin antibiotic. The same chimeric kan gene in a tobacco targeting plasmid (plasmids pTNH32) was used for direct selection of plastid transformants in tobacco (Carrer et al. 1993) The construction of the kan gene was described in more detail in this same reference. Plasmid pGS85A was obtained by excising kan from pTNH7 as a SacI/PstI fragment, blunting, and cloning the fragment into the HincII site of plasmid pGS7 (FIG. 4). The kan gene in pGS85A, as aadA in plasmid pGS31A, is expressed in a Prrn/TpsbA cassette. However, the five N-terminal amino acids of the highly-expressed rbcl coding region were translationally fused with the neomycin phosphotransferase N-terminus. This translational fusion in tobacco lead to the accumulation of NPTII at 10× higher levels than from identical constructs without the rbcl N-terminal segment. The DNA sequence of pGS85A, including that of the chimeric kan gene, is set forth herein.

Initially, seed-set was tested in plants regenerated via the tissue culture protocol. Selection of kanamycin resistant clones after bombardment with DNA-coated tungsten was subsequently assessed. These improvements to the method are suitable for the generation of fertile, transformed Arabidopsis plants. The following material and protocols were utilized in practicing the methods of this Example II.

Seed Germination

Seeds of Arabidopsis thaliana ecotype RLD are surface sterilized using commercial bleach (5% sodium hypochlorite) for 5 minutes followed by a subsequent 5 minute treatment with 95% ethanol. A drop of Triton X-100 was added to the bleach to wet the surface of the seeds during the sterilization period. After sterilization, seeds were washed 5-6 times with sterile deionized water. Seeds were germinated on GM medium in 10 cm Petri dishes. See Table 2. The Petri dishes were incubated for 8 to 9 days in a Percival growth chamber at 23° C. under continous light.

TABLE 2 Composition of seed germination (GM) medium. Medium Concentration (mg/L) MS basal salts 0.5 X myo-inositol 100 Thiamine 0.1 Pyridoxine 0.5 Nicotinic acid 0.5 Glycine 2.0 Sucrose 30 g/L pH 5.8

Reference: van der Graaff and Hooykaas, 1996.

Tissue Culture Media and Culture Conditions

Compositions of the tissue culture media used for Stages I, II and III of the selection protocol are listed in Tables 2 and 3. Stage I and Stage II liquid cultures were established by aseptically transferring at least 50 to 2000 cotyledons to a Petri dish (100 mm×20 mm), each dish containing approximately 20 ml of medium. The Petri dishes were incubated at 23° C. on a New Brunswick G10 gyrotory shaker at 60 rpm and illuminated for 16 hours with cool fluorescent light. In the Stage III protocol, cotyledons were incubated on agar-solidified (0.8% TC agar, JRH Biosciences) media at approximately 25-30 cotyledons per Petri dish (100 mm×20 mm) in 50 ml of media. The cultures were illuminated as described for Stages I and II.

Regenerated plants were directly transferred to GM medium in Magenta boxes with vented lids for gas exchange. Plants in the Magenta boxes were incubated in the culture room at 23° C.; and illuminated for 16 hours with cool fluorescent light. The plants flowered and set seeds in the boxes.

The methods described for Example I were modified to generate fertile Arabidopsis plants having transformed plastid genomes. Three distinct tissue culture stages were employed to obtain plastid transformation. Stage I: liquid culture, in high auxin medium to stimulate uniform cell division. Stage II: liquid culture, in high cytokinin medium to induce plant regeneration from the transformed cells. Stage III: culture on agar-solidified medium, containing high levels of cytokinins also to induce plant regeneration.

A schematic diagram of the strategy used to identify the best protocol for obtaining fertile plastid transformants is outlined in FIG. 3. To induce uniform cell division in liquid culture, four media, C1 (van der Graaff and Hooykaas, 1996), ARM I (Marton and Browse, 1991), R3 and PG1 (Feldmann and Marks, 1986; reported to induce callus and/or somatic embryogenesis in Arabidopsis) were utilized. Stage I treatment was kept short (2 days) to adopt to the usual timing of transferring the explants to a selective medium after bombardment, and to minimize the adverse effect of 2-4-D, if used at all. The composition of the Stage I tissue culture media utilized is set forth in Table 3 below.

TABLE 3 Composition of Stage I tissue culture media*. Media ARM I C1 R3 PG1 Basal salts MS MS MS MS Vitamins ARM I B5 MS B5 2,4-D 0.15 — 0.5 2.2 BAP 0.6 0.2 — — IAA 3.0 — 5.0 — IPA 0.3 — — — NAA — 1.0 — — KIN — — 0.3 0.05 Sucrose 30 g 30 g 30 g 30 g pH 5.8 5.8 5.8 5.8 *All components are in mg/L. References: ARM1, Marton and Browse, 1991; C1, van der Graaff and Hooykaas, 1996; R3 and PG1, Feldmann and Marks (1986).

For Stage II culture, only one medium (A; Table 4) was used. This medium was efficient for inducing plant regeneration from immature cotyledons (Patton and Meinke, 1988). The cotyledons at Stage II were kept for a total of 6 additional days at high density in liquid culture.

For Stage III culture, the cotyledons were transferred to four types of agar-solidified regeneration media. These include the A medium developed for plant regeneration from immature embryos (Patton and Meinke, 1988); the B medium developed for plant regeneration from root explants (ARMII; Marton and Browse, 1991); the C medium that designed herein; and the D medium which is an embryo-induction medium for roots (ARMI; Marton and Browse, 1991) and leaf explants (Example I).

TABLE 4 Stage II and Stage III plant regeneration media. Media A medium* B medium* C medium* D medium* Basal salts MS MS MS MS Vitamins B5 B5 B5 B5 NAA 0.1 — 0.1 — IAA — 0.1 — 3.0 BAP 1.0 — 1.0 0.6 2iP — 4.0 2.0 0.3 2,4-D — — — 0.15 Sucrose 30 g 30 g 30 g 30 g Agar (TC)  7 g  7 g  7 g  7 g pH 5.8 5.8 5.8 5.8 *All components are in mg/L. A medium is based on Patton and Meinke, 1988; B medium is the same as ARMII in Marton and Bowse, 1991; C medium developed herein, based on A and D media; D medium is the same as ARMI embryo-induction medium in Marton and Browse, 1991.

Plant Regeneration and Testing of Fertility

Cotyledons remained green and slightly expanded in size during the first 2 days of culture at Stage I in all four media. After 2 days in callus/embryo induction medium, cotyledons for Stage II were transferred from all four media to the A liquid regeneration medium. Green callus started appearing after 3 days of culture in A medium and by the 7th day callus appeared all over the cotyledons. At this stage cultures were transferred to the semi-solid media of Stage III which promotes embryo/shoot growth. Calli derived from media 1 (ARM1) and 2 (C1) were green. Development of plantlets from these explants could be seen by 21 days of culture. Callus derived from media 3 (R3) and 4 (PG1) was also green but very compact. This is probably due to the high concentration of 2,4-D in the Stage I media. A few plantlets in these cultures appeared only after 30 days. Plants from all cultures were transferred to hormone free GM medium as soon as they were 5-10 mm in size.

The protocols diagrammed in FIG. 3 were evaluated at two levels: uniform induction of cell division and shoot regeneration from the cotyledons; and by production of viable seed on the regenerated plants. The results are summarized in Table 5. Based on the first criterion, the best combination was 2AC, that is C1 medium at Stage I and C medium at Stage III, these treatments resulted in prolific shoot regeneration which was observed on each of the explants. The second best combination was 1AC (35 out of 40 explants regenerating shoots), with ARM1 at Stage I and medium C at Stage III. Combinations with media 3 and 4 at Stage I performed very poorly, with only a very small fraction of cotyledons forming shoots.

As to formation of viable seed, with one exception each of the regenerated plants produced viable seed. See Table 5. Most importantly, no adverse effect on fertility was found in the two combinations (2AC and 1AC) in which shoot regeneration is prolific.

TABLE 5 Seed-set in Magenta boxes an Arabidapsis thaliana RLD plants regenerated via plastid transformation protocols schematically shown in FIG. 3. Number of Number of Number of Number of cotyledons cotyledons plants with viable Media cultured with shoots in boxes seed 1AA 40 20 8 8 1AB 40 25 8 8 1AC 40 35 8 8 1AD 40 — — — 2AA 40 25 12 12 2AB 40 22 8 7 2AC 40 40 16 16 2AD 40 2 — — 3AA 40 12 4 4 3AB 40 6 4 4 3AC 40 20 — — 3AD 40 1 — — 4AA 40 1 — — 4AB 40 1 — — 4AC 40 4 4 4 4AD 40 1 — 1

Selection of Plastid Transformants by Kanamycin Resistance

Expression of kan encoding neomycin phosphotransferase (NPTII) confers resistance to kanamycin when introduced into the Arabidopsis nucleus. Engineered forms of ksn have been extensively used to obtain nuclear transformants in Arabidopsis, see Valvekens et al., 1998. and Brassica, see Radke, et al. 1992. The kan gene has been converted into a plastid marker for the selection of plastid transformants in tobacco (Carrer et al., 1993). As set forth in Example I, Aradiposis plastid transformants have been obtained by selection for spectinomycin resistance conferred by aadA in the tobacco Prrn/TpsbA cassette. Prrn is a promoter derived from the plastid rRNA operon and TpsbA contains the plastid psbA gene 3′ untranslated region required for the stabilization of chimeric plastid mRNAs (Svab and Maliga, 1993). A kanamycin resistance marker gene suitable for the selection of plastid transformants may be obtained by expressing kan in the Prrn/TpsbA cassette. A suitable kanamycin resistance plastid transformation vector from Arabidopsis and Brassica is the pGS85A vector which carries the chimeric kanamycin gene from plasmid pTNH32 (Carrer et al. 1993). The insertion site in pGS85A is the Hinc II site in the trnV/rps12/7 intergenic region. However, other intergenic regions in the plastid genome may be targeted, providing the introduced transgene does not interfere with the expression of the flanking plastid genes.

Plastid transformation may be carried out following the 1AC or 2AC tissue culture protocols outlined above. To prepare a suitable target tissue for transformation, cotyledons from 8-9 day old seedlings are cut from seedlings in liquid ARM1 and C1 media and cultured for two days as dictated by the 1AC and 2AC protocols (FIG. 3). After two days the cotyledons are transferred to filter paper (Whatman No. 4) on agar-solidified non-selective medium of identical composition. Approximately 50 to 70 cotyledons are required to cover a 3 cm² area. The cotyledons are then bombarded with plasmid pGS85A, a kanamycin resistance, transforming Arabidopsis vector. Plasmid preparation, coating of tungsten particles and bombardment should be carried out as described for tobacco (Maliga, 1995). For phenotypic expression, the cotyledons may be left in the same plates for two days. Subsequently, the cotyledons may be transferred to a selective liquid A medium containing 50 mg/L kanamycin sulfate and cultured for an additional seven days. After 7 days, cotyledons are transferred to a selective, agar-solidified C medium containing 50 mg/L kanamycin. In an alternative embodiment, selection may be carried out initially using kanamycin at 25 mg/ml. At later stages of culture, the kanamycin concentration is increased to 50 mg/ml. Callus growth from the transformed cells on the selective medium may be observed as early as one week. However, additional kanamycin-resistant clones may appear for several more weeks. Some of these are plastid transformants, while others acquire resistance to kanamycin due to the expression of the plastid kan gene in the nucleus (Carrer et al., 1993). The two classes of kanamycin-resistant clones can be readily distinguished DNA gel blot analysis and PCR analysis (as described in Example I). DNA was amplified according to standard protocols (1 min at 92° C., 1.5 min at 58° C., 1.5 min at 72° C., 30 cycles). Kanamycin resistance occurs as the result of neomycin phosphotransferase gene expression which may be verified by PCR amplification of a 548 nucleotide internal segment using the following primers:

5′-CCGACCTGTCCGGTGCCC-3′

5′-CACGACGAGATCCTCGCCG-3′.

EXAMPLE III Plastid Transformation in Brassica napus Leaves by Selection for Resistance to Spectinomycin and Kanamycin

Given their essentially identical genomes, plastid transformation vectors and expression cassettes developed for Arabidopsis can be used to advantage for plastid transformation and expression of foreign genes in Brassica species without modification.

Certain plastid expression signals derived from evolutionarily distant species function in Arabidopsis and Brassica plastids. This observation is supported by the results described in Example I demonstrating that the tobacco Prrn/TpsbA cassette can be used for expressing the selectable spectinomycin resistance gene (aadA) in Arabidopsis plastids. However, not every tobacco expression signal functions properly in Arabidopsis. Studies with a vector identical to PGS31A, except that the termination signal TpsbA, has been replaced with signal Trps16 has a dramatic effect on obtaining plastid transformants. This plasmid gene was obtained by inserting the Prrn/Trps16 cassette into targeting site in the pGS7 vector. See FIG. 4. Zero plastid transformants were obtained out of 416 samples bombarded with this plasmid. As mentioned above, when a Prrn/TpsbA cassette (cassettes described in Staub and Maliga, Plant Journal 6:547-553, 1994 and Svab and Maliga, 1993, the subject matter of which is incorporated herein by reference) was utilitized to transform Arabidopsis leaves, plastid transformants were obtained, 2 out of 210 samples bombarded.

Due to their taxonomic relatedness, Arabidopsis and Brassica species respond similarly in tissue culture to plant hormones or to antibiotics. As a result, plant regeneration from cultured cells and selection of transgenic lines by antibiotic resistance may be accomplished by essentially the same protocol. Both Arabidopsis and Brassica leaf or cotyledon explants respond to 500 mg/L spectinomycin with prolific callus growth in wild-type, non-transformed tissue on shoot regeneration medium, such as medium C described in Table 6. This response differs significantly in tobacco leaf tissue wherein exposure to 500 mg/ml of spectinomycin results in a severe inhibition of callus proliferation on shoot induction medium. Thus, tobacco plastid (and nuclear gene) transformants can be readily regenerated on a shoot induction medium containing spectinomycin at 500 mg/L (Svab and Maligam 1993). Unfortunately, rapid callus proliferation on spectinomycin-containing C shoot/embryo regeneration medium (see table 6) prevents the recovery of Arabidopsis and Brassica plastid transformants. Culture conditions must be improved to suppress rapid callus growth to facilitate the recovery of plastid transformants. Such conditions are outlined in Example I. While selection was feasible and plastid transformants were obtained using the methods of Example I, the transplastomic plants generated were not fertile. However, given the higher tolerance of Brassica to 2,4 D (Radke et al., 1992) the same protocol described in example I may be adapted for use in Brassica.

The data presented in Example II indicate that kanamycin selection is compatible with the regeneration protocols described. Accordingly, kanamycin is the favored antibiotic for the selection of plastid transformants in the Cruciferae taxonomic group.

Examples I and II disclose protocols for the regeneration of transgenic plants from Arabidopsis leaves and cotyledons. A protocol for the regeneration of transgenic plants in Brassica would involve a two-stage protocol (application of two different media) for leaves, and a three-stage protocol (application of three different media) for cotyledons. The three-stage protocol described for use in the plastid transformation of Arabidopsis cotyledons in Example II is suitable for use in Brassica. Accordingly only the methods for transforming Brassica leaf plastids in a two stage process will be described below

Plastid Transformation in Brassica Utilizing Leaves as Target Tissue and Kanamycin Resistance as the Selective Marker

Brassica Stage I culture results in the uniform induction of cell division in leaves or cotyledons. The objective of Stage II is regeneration of transgenic plants. A suitable Stage I medium for the induction of cell division would be the ARMI medium discussed in Examples I and II. Suitable Stage II regeneration media would be the B medium (ARMII in Marton and Browse, 1991), C medium (this study) and E medium (Pelletier et al. 1983) listed in Table 6.

TABLE 6 Stage II Brassica plant regeneration media* Media B medium C medium E medium Basal salts MS MS MS Vitamins B5 B5 B5 NAA — 0.1 1.0 IAA 0.1 — — BAP — 1.0 — 2iP 4.0 2.0 1.0 GA3 — —  0.02 Sucrose 30 g 30 g 30 g Agar (TC)  7 g  7 g  7 g pH 5.8 5.8 5.8 *All components are in mg/L. B medium is the same as ARMII in Marton and Bowse, 1991; C medium is this study; E medium is the cruciferae

For selection of plastid transformants, Brassica napus cv. Westar seeds should be surface sterilized, and germinated aseptically in Magenta boxes as described for Arabidopsis in Example II. After three to four weeks, the leaves are harvested, and directly placed a Whatman filter paper placed on agar-solidified non-selective Stage I medium. Following bombardment with DNA of the appropriate plastid transformation vector carrying a selectable kanamycin-resistance marker, as described in Example II, the plates are incubated for two days in the light (16 hours) at 25° C. After 2 days the leaves are incised with a stack of sterile razor blades, and transferred to the same Stage I medium supplemented with 50 mg/L of kanamycin sulfate. In an alternative embodiment, selection may be carried out initially using kanamycin at 25 mg/ml. At later stages of culture, the kanamycin concentration is increased to 50 mg/ml. After two weeks on the selective Stage I medium, the leaves are transferred to one of the Stage II media for plant regeneration. Kanamycin resistant clones are identified by their rapid growth and shoot regeneration on the selection medium. Kanamycin resistance may be due to plastid transformation or integration of the kanamycin marker gene into the nuclear genome. Plastid transformation is verified by PCR and DNA gel blot analysis in tissue samples taken from kanamycin-resistant calli and regenerating shoots. The regenerated shoots are then rooted and transferred to soil in the greenhouse following standard protocols.

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While certain preferred embodiments of the present invention have been described and specifically exemplified above, it is not intended that the invention be limited to such embodiments. Various modifications may be made to the invention without departing from the scope and spirit thereof as set forth in the following claims.

7 1 19 DNA Artificial Sequence Sequence Source/note=“synthetic sequence” 1 gcttgatgaa acaacgcgg 19 2 25 DNA Artificial Sequence Sequence source/note=“synthetic sequence” 2 ccaagcgatc ttcttcttgt ccaag 25 3 18 DNA Artificial Sequence Sequence source/note=“synthetic sequence” 3 ccgacctgtc cggtgccc 18 4 19 DNA Artificial Sequence Sequence source/note=“synthetic sequence” 4 cacgacgaga tcctcgccg 19 5 1993 DNA Arabidopsis thaliana unsure (483)...(483) The residue at position 483 may be A, T, C or G. 5 aagcttggta gtttccaccg cctgtccagg gttgagccct gggatttgac ggcggactta 60 aaaagccacc tacagacgct ttacgcccaa tcattccgga taacgcttgc atcctctgta 120 ttaccgcggc tgctggcaca gagttagccg atgcttattc cccagatacc gtcattgctt 180 cttctctggg aaaagaagtt caggacccgt aggccttcta cctccacgcg gcattgctcc 240 gtcaggcttt cgcccattgc ggaaaattcc ccactgctgc ctcccgtagg agtctgggcc 300 gtgtctcagt cccagtgtgg ctgatcatcc tctcggacca gctactgatc atcgccttgg 360 taagctattg cctcaccaac tagctaatca gacgcgagcc cctcctcggg cggattcctc 420 cttttgctcc tcagctacgg ggtattagca gccgtttcca gctgttgttc ccctcccaag 480 ggnaggttct tacgcgttac tcaccngtcc gccactggaa acaccacttc ccgtccgact 540 tgcatgtgtt aagcatgccg ccagcgttca tcctgagcca ggatcgaact ctccatgaga 600 ttcatagttg cattacttat agcttccttc ttcgtagaca aagctgattc ggaattgtct 660 ttcattccaa gtcataactt gtatccatgc gcttcatatt cgcatggagt tcgctcccag 720 aaatatagct acccctaccc cctcacgtca atcccacgag cctcttatcc attcttattc 780 gatcacagcg agggagcaag tcaaaataga aaaactcaca ttcattgggt ttagggataa 840 tcaggctcga actgatgact tccaccacgt caaggtgaca ctctaccgct gagttatatc 900 ccttccccca tcaagaaata gaactgacta atcctaagtc aaagggtcga gaaactcaag 960 gccactattc ttgaacaact tggattggag ccgggctttc ctttcgcact ttatacgggt 1020 atgaaatgaa aataatggaa aaagttggat tcaattgtca actactccta tcggaaatag 1080 gattgactac ggattcgagc catagcacat ggtttcataa aaccgtacga ttctcccgat 1140 ctaaatcaag ccggttttac atgaagaaga tttgactcgg catgttctat tcgatacggg 1200 taggagaaac ggtattcttt tcttaaactt caaaaaatag agaaataaga accaagtcaa 1260 gatgatacgg attaatcctt tattcttgcg ccaaagatct tcctattcca aggaactgga 1320 gttacatctc ttttccattt ccattcaaga gttcttatgt gtttccacgc ccctttaaga 1380 ccccgaaaaa tcgacaaatt cccttttctt aggaccacat gcgagataac gaaaaaaaaa 1440 aagagagaat ggtaacccca cgattaacta ttttatttat gaatttcata gtaatagaaa 1500 tacatgtcct accgaaacag aatttgtaac ttgctatcct atcatcttgc ctagcaggca 1560 aagatttcac tccgcgaaaa agatgattca ttcggatcaa catgaaagcc caactacatt 1620 gccagaattt atatattgga aagaggttta cctccttgct tctatggtac aatcctcttc 1680 ccgcggagcc tcctttcttc tcggtccgca gagacaaaat gtaggactgg tgccaacagt 1740 taatcacgga agaaaggact cactgcgcca agatcactaa ctaatctaat agaatagaaa 1800 atcctaatat aatagaaaag aaaagaactg tcttttctga tacttatgta tactttcccc 1860 ggttccgttg ctactgcggn tttacgcaat tgatcggatc atctagatat cccttcaaca 1920 caacataggt cgtcgaaagg atctcggaga cccgccaaag cacgaaagcc agaatctttc 1980 agaaaatgaa ttc 1993 6 1143 DNA Nicotiana tabacum 6 catgaataaa tgcaagaaaa taacctctcc ttctttttct ataatgtaaa caaaaaagtc 60 tatgtaagta aaatactagt aaataaataa aaagaaaaaa agaaaggagc aatagcaccc 120 tcttgataga acaagaaaat gattattgct cctttctttt caaaacctcc tatagactag 180 gccaggatcg ctctagctag acattatttg ccgactacct tggtgatctc gcctttcacg 240 tagtggacaa attcttccaa ctgatctgcg cgcgaggcca agcgatcttc ttcttgtcca 300 agataagcct gtctagcttc aagtatgacg ggctgatact gggccggcag gcgctccatt 360 gcccagtcgg cagcgacatc cttcggcgcg attttgccgg ttactgcgct gtaccaaatg 420 cgggacaacg taagcactac atttcgctca tcgccagccc agtcgggcgg cgagttccat 480 agcgttaagg tttcatttag cgcctcaaat agatcctgtt caagaaccgg atcaaagagt 540 tcctccgccg ctggacctac caaggcaacg ctatgttctc ttgcttttgt cagcaagata 600 gccagatcaa tgtcgatcgt ggctggctcg aagatacctg caagaatgtc attgcgctgc 660 cattctccaa attgcagttc gcgcttagct ggataacgcc acggaatgat gtcgtcgtgc 720 acaacaatgg tgacttctac agcgcggaga atctcgctct ctccagggga agccgaagtt 780 tccaaaaggt cgttgatcaa agctcgccgc gttgtttcat caagccttac ggtcaccgta 840 accagcaaat caatatcact gtgtggcttc aggccgccat ccactgcgga gccgtacaaa 900 tgtacggcca gcaacgtcgg ttcgagatgg cgctcgatga cgccaactac ctctgatagt 960 tgagtcgata cttcggcgac caccgcttct gccataaatc cctccctaca actgtatcca 1020 agcgcttcgt attcgcccgg agttcgctcc cagaaatata gccatccctg ccccctcacg 1080 tcaatcccac gagcctctta tccattctca ttgaacgacg gcgggggagc tttgggtacc 1140 gag 1143 7 1417 DNA Artificial Sequence Sequence source/note=“synthetic construct” 7 gaattcgagc tcggtaccca aagctccccc gccgtcgttc aatgagaatg gataagaggc 60 tcgtgggatt gacgtgaggg ggcagggatg gctatatttc tgggagcgaa ctccgggcga 120 atacgaagcg cttggataca gttgtaggga gggatttatg tcaccacaaa cagaggggat 180 tgaacaagat ggattgcacg caggttctcc ggccgcttgg gtggagaggc tattcggcta 240 tgactgggca caacagacaa tcggctgctc tgatgccgcc gtgttccggc tgtcagcgca 300 ggggcgcccg gttctttttg tcaagaccga cctgtccggt gccctgaatg aactccagga 360 cgaggcagcg cggctatcgt ggctggccac gacgggcgtt ccttgcgcag ctgtgctcga 420 cgttgtcact gaagcgggaa gggactggct gctattgggc gaagtgccgg ggcaggatct 480 cctgtcatct caccttgctc ctgccgagaa agtatccatc atggctgatg caatgcggcg 540 gctgcatacg cttgatccgg ctacctgccc attcgaccac caagcgaaac atcgcatcga 600 gcgagcacgt actcggatgg aagccggtct tgtcgatcag gatgatctgg acgaagagca 660 tcaggggctc gcgccagccg aactgttcgc caggctcaag gcgcgcatgc ccgacggcga 720 ggatctcgtc gtgacacatg gcgatgcctg cttgccgaat atcatggtgg aaaatggccg 780 cttttctgga ttcatcgact gtggccggct gggtgtggcg gaccgctatc aggacatagc 840 gttggctacc cgtgatattg ctgaagagct tggcggcgaa tgggctgacc gcttcctcgt 900 gctttacggt atcgccgctc ccgattcgca gcgcatcgcc ttctatcgcc ttcttgacga 960 gttcttctga gcgggactct ggggttcgga tcgatcctct agagcgatcc tggcctagtc 1020 tataggaggt tttgaaaaga aaggagcaat aatcattttc ttgttctatc aagagggtgc 1080 tattgctcct ttcttttttt ctttttattt atttactagt attttactta catagacttt 1140 tttgtttaca ttatagaaaa agaaggagag gttattttct tgcatttatt catgattgag 1200 tattctattt tgattttgta tttgtttaaa ttgtgaaata gaacttgttt ctcttcttgc 1260 taatgttact atatcttttt gatttttttt ttccaaaaaa aaaatcaaat tttgacttct 1320 tcttatctct tatctttgaa tatctcttat ctttgaaata ataatatcat tgaaataaga 1380 aagaagagct atattcgacc tgcaggcatg caagctt 1417 

What is claimed is:
 1. A method for obtaining transplastomic Arabidopsis plants, comprising: a) culturing Arabidopsis plant cells from said Arabidopsis plant in a high auxin containing medium that stimulates uniform cell division; b) transferring said plant cells to filter paper on agar-solidified medium; c) delivering to a plastid genome within said plant cells, a transforming DNA molecule, said transforming DNA molecule having; i) a plurality of targeting segments comprising plastid DNA sequences from said plastid genome to be transformed, said targeting segments facilitating homologous recombination of said transforming DNA into said plastid genome; ii) 5′ and 3′ regulatory sequences derived from plastid DNA operably linked to a selectable marker gene disposed within said targeting segment, said regulatory sequences facilitating expression of the selectable marker gene and stability of mRNA encoded therefrom, said selectable marker gene conferring resistance to a selection agent in said plant cells; iii) 5′ and 3′ regulatory sequences derived from plastid DNA operably linked to coding sequences comprising a foreign gene of interest thereby facilitating expression of the foreign gene of interest and stability of mRNA encoded therefrom; and iv) at least one cloning site for insertion of said foreign gene of interest adjacent to said selectable marker gene, said insertion not interfering with said conferring of said selectable phenotype and function of flanking plastid genes; d) transferring cells transformed as in step (c) to an agar-solidified high cytokinin containing culture medium at high density for a predetermined time period; said culture medium containing an agent that promotes plant regeneration; e) transferring said cells treated as in step (d) to an agar-solidified culture medium containing said regeneration promoting agent and said selection agent, said transformed cells being rendered resistant to said selection agent by expression of said selectable maker gene; and f) selecting for cells having transformed plastid genomes and inducing plant regeneration therefrom.
 2. A method as claimed in claim 1, wherein said transforming DNA is delivered by a method selected from the group consisting of biolistic bombardment of said cells with DNA-coated particles, CaPO₄ mediated transfection, electroporation, and polyethylene glycol mediated DNA uptake.
 3. A method claimed as in claim 1, wherein said plant cells are selected from the group consisting of cotyledon cells, leaf cells, hypocotyls and root cells.
 4. A method as claimed in claim 1, wherein said selectable marker gene and said foreign gene of interest constitute a monocistronic expression unit.
 5. A method as claimed in claim 1, wherein said selectable marker gene and said foreign gene of interest constitute a polycistronic expression unit.
 6. A method as claimed in claim 1, wherein said plastids are chloroplasts.
 7. A method as claimed in claim 1, wherein said antibiotic is selected from the group consisting of kanamycin, spectinomycin, and streptomycin.
 8. A method as claimed in claim 1, wherein said agent promoting uniform cell division is selected from the group consisting of NAA, IAA, and 2,4-D.
 9. A method as claimed in claim 1, wherein said regeneration promoting agent is selected from the group consisting of BAP, 2iP, IPA and KIN.
 10. A method as claimed in claim 1, wherein said transforming DNA is cloned within vector pGS31A.
 11. A method as claimed in claim 1, wherein said transforming DNA is cloned within vector pGS85A.
 12. A method as claimed in claim 1, wherein said transforming DNA is cloned within vector PGS7.
 13. A method as claimed in claim 1, wherein said plant is Arabidopsis thaliana. 